Investigating Quantum Error Mitigation Strategies in Small-Scale Surface Codes: A Study of Depolarizing Noise Thresholds

The issue of error-prone quantum information obstructs the progress of quantum computing, notwithstanding its capacity to transform complex problem-solving. This study examines the impact of depolarizing noise on a 5-qubit, distance-2 surface code, representing a fundamental quantum error correcting (QEC) frame- work. The primary objective is to identify a breakeven error rate beneath which error correction remains effective. We assess logical error rates through simu- lation across different noise levels, identifying a crucial breakeven threshold at around a 10% error rate. Below this level, the surface code exhibits proficient mistake detection; but, beyond this point, the effectiveness of repair diminishes significantly. We examine quantum error mitigation (QEM) techniques such as syndrome amplification and post-selection to evaluate their efficacy in minimiz- ing errors within the threshold range. We also noted spatial connections in error patterns, suggesting possible pathways for focused mistake correction. These find- ings elucidate the functioning of quantum error correction (QEC) in small-scale codes and underscore the necessity for noise-aware QEC techniques in scalable quantum systems.